/******************************************************************************
 *
 * Project:  GDAL
 * Purpose:  Compute each pixel's proximity to a set of target pixels.
 * Author:   Frank Warmerdam, warmerdam@pobox.com
 *
 ******************************************************************************
 * Copyright (c) 2008, Frank Warmerdam
 * Copyright (c) 2009-2010, Even Rouault <even dot rouault at spatialys.com>
 *
 * SPDX-License-Identifier: MIT
 ****************************************************************************/

#include "cpl_port.h"
#include "gdal_alg.h"

#include <cmath>
#include <cstdlib>

#include <algorithm>

#include "cpl_conv.h"
#include "cpl_error.h"
#include "cpl_progress.h"
#include "cpl_string.h"
#include "cpl_vsi.h"
#include "gdal.h"

static CPLErr ProcessProximityLine(GInt32 *panSrcScanline, int *panNearX,
                                   int *panNearY, int bForward, int iLine,
                                   int nXSize, double nMaxDist,
                                   float *pafProximity,
                                   double *pdfSrcNoDataValue, int nTargetValues,
                                   int *panTargetValues);

/************************************************************************/
/*                        GDALComputeProximity()                        */
/************************************************************************/

/**
Compute the proximity of all pixels in the image to a set of pixels in
the source image.

This function attempts to compute the proximity of all pixels in
the image to a set of pixels in the source image.  The following
options are used to define the behavior of the function.  By
default all non-zero pixels in hSrcBand will be considered the
"target", and all proximities will be computed in pixels.  Note
that target pixels are set to the value corresponding to a distance
of zero.

The progress function args may be NULL or a valid progress reporting function
such as GDALTermProgress/NULL.

Options:

  VALUES=n[,n]*

A list of target pixel values to measure the distance from.  If this
option is not provided proximity will be computed from non-zero
pixel values.  Currently pixel values are internally processed as
integers.

  DISTUNITS=[PIXEL]/GEO

Indicates whether distances will be computed in pixel units or
in georeferenced units.  The default is pixel units.  This also
determines the interpretation of MAXDIST.

  MAXDIST=n

The maximum distance to search.  Proximity distances greater than
this value will not be computed.  Instead output pixels will be
set to a nodata value.

  NODATA=n

The NODATA value to use on the output band for pixels that are
beyond MAXDIST.  If not provided, the hProximityBand will be
queried for a nodata value.  If one is not found, 65535 will be used.

  USE_INPUT_NODATA=YES/NO

If this option is set, the input data set no-data value will be
respected. Leaving no data pixels in the input as no data pixels in
the proximity output.

  FIXED_BUF_VAL=n

If this option is set, all pixels within the MAXDIST threshold are
set to this fixed value instead of to a proximity distance.
*/

CPLErr CPL_STDCALL GDALComputeProximity(GDALRasterBandH hSrcBand,
                                        GDALRasterBandH hProximityBand,
                                        char **papszOptions,
                                        GDALProgressFunc pfnProgress,
                                        void *pProgressArg)

{
    VALIDATE_POINTER1(hSrcBand, "GDALComputeProximity", CE_Failure);
    VALIDATE_POINTER1(hProximityBand, "GDALComputeProximity", CE_Failure);

    if (pfnProgress == nullptr)
        pfnProgress = GDALDummyProgress;

    /* -------------------------------------------------------------------- */
    /*      Are we using pixels or georeferenced coordinates for distances? */
    /* -------------------------------------------------------------------- */
    double dfDistMult = 1.0;
    const char *pszOpt = CSLFetchNameValue(papszOptions, "DISTUNITS");
    if (pszOpt)
    {
        if (EQUAL(pszOpt, "GEO"))
        {
            GDALDatasetH hSrcDS = GDALGetBandDataset(hSrcBand);
            if (hSrcDS)
            {
                double adfGeoTransform[6] = {0.0, 0.0, 0.0, 0.0, 0.0, 0.0};

                GDALGetGeoTransform(hSrcDS, adfGeoTransform);
                if (std::abs(adfGeoTransform[1]) !=
                    std::abs(adfGeoTransform[5]))
                    CPLError(
                        CE_Warning, CPLE_AppDefined,
                        "Pixels not square, distances will be inaccurate.");
                dfDistMult = std::abs(adfGeoTransform[1]);
            }
        }
        else if (!EQUAL(pszOpt, "PIXEL"))
        {
            CPLError(
                CE_Failure, CPLE_AppDefined,
                "Unrecognized DISTUNITS value '%s', should be GEO or PIXEL.",
                pszOpt);
            return CE_Failure;
        }
    }

    /* -------------------------------------------------------------------- */
    /*      What is our maxdist value?                                      */
    /* -------------------------------------------------------------------- */
    pszOpt = CSLFetchNameValue(papszOptions, "MAXDIST");
    const double dfMaxDist = pszOpt ? CPLAtof(pszOpt) / dfDistMult
                                    : GDALGetRasterBandXSize(hSrcBand) +
                                          GDALGetRasterBandYSize(hSrcBand);

    CPLDebug("GDAL", "MAXDIST=%g, DISTMULT=%g", dfMaxDist, dfDistMult);

    /* -------------------------------------------------------------------- */
    /*      Verify the source and destination are compatible.               */
    /* -------------------------------------------------------------------- */
    const int nXSize = GDALGetRasterBandXSize(hSrcBand);
    const int nYSize = GDALGetRasterBandYSize(hSrcBand);
    if (nXSize != GDALGetRasterBandXSize(hProximityBand) ||
        nYSize != GDALGetRasterBandYSize(hProximityBand))
    {
        CPLError(CE_Failure, CPLE_AppDefined,
                 "Source and proximity bands are not the same size.");
        return CE_Failure;
    }

    /* -------------------------------------------------------------------- */
    /*      Get input NODATA value.                                         */
    /* -------------------------------------------------------------------- */
    double dfSrcNoDataValue = 0.0;
    double *pdfSrcNoData = nullptr;
    if (CPLFetchBool(papszOptions, "USE_INPUT_NODATA", false))
    {
        int bSrcHasNoData = 0;
        dfSrcNoDataValue = GDALGetRasterNoDataValue(hSrcBand, &bSrcHasNoData);
        if (bSrcHasNoData)
            pdfSrcNoData = &dfSrcNoDataValue;
    }

    /* -------------------------------------------------------------------- */
    /*      Get output NODATA value.                                        */
    /* -------------------------------------------------------------------- */
    float fNoDataValue = 0.0f;
    pszOpt = CSLFetchNameValue(papszOptions, "NODATA");
    if (pszOpt != nullptr)
    {
        fNoDataValue = static_cast<float>(CPLAtof(pszOpt));
    }
    else
    {
        int bSuccess = FALSE;

        fNoDataValue = static_cast<float>(
            GDALGetRasterNoDataValue(hProximityBand, &bSuccess));
        if (!bSuccess)
            fNoDataValue = 65535.0;
    }

    /* -------------------------------------------------------------------- */
    /*      Is there a fixed value we wish to force the buffer area to?     */
    /* -------------------------------------------------------------------- */
    double dfFixedBufVal = 0.0;
    bool bFixedBufVal = false;
    pszOpt = CSLFetchNameValue(papszOptions, "FIXED_BUF_VAL");
    if (pszOpt)
    {
        dfFixedBufVal = CPLAtof(pszOpt);
        bFixedBufVal = true;
    }

    /* -------------------------------------------------------------------- */
    /*      Get the target value(s).                                        */
    /* -------------------------------------------------------------------- */
    int *panTargetValues = nullptr;
    int nTargetValues = 0;

    pszOpt = CSLFetchNameValue(papszOptions, "VALUES");
    if (pszOpt != nullptr)
    {
        char **papszValuesTokens =
            CSLTokenizeStringComplex(pszOpt, ",", FALSE, FALSE);

        nTargetValues = CSLCount(papszValuesTokens);
        panTargetValues =
            static_cast<int *>(CPLCalloc(sizeof(int), nTargetValues));

        for (int i = 0; i < nTargetValues; i++)
            panTargetValues[i] = atoi(papszValuesTokens[i]);
        CSLDestroy(papszValuesTokens);
    }

    /* -------------------------------------------------------------------- */
    /*      Initialize progress counter.                                    */
    /* -------------------------------------------------------------------- */
    if (!pfnProgress(0.0, "", pProgressArg))
    {
        CPLError(CE_Failure, CPLE_UserInterrupt, "User terminated");
        CPLFree(panTargetValues);
        return CE_Failure;
    }

    /* -------------------------------------------------------------------- */
    /*      We need a signed type for the working proximity values kept     */
    /*      on disk.  If our proximity band is not signed, then create a    */
    /*      temporary file for this purpose.                                */
    /* -------------------------------------------------------------------- */
    GDALRasterBandH hWorkProximityBand = hProximityBand;
    GDALDatasetH hWorkProximityDS = nullptr;
    const GDALDataType eProxType = GDALGetRasterDataType(hProximityBand);
    CPLErr eErr = CE_None;

    // TODO(schwehr): Localize after removing gotos.
    float *pafProximity = nullptr;
    int *panNearX = nullptr;
    int *panNearY = nullptr;
    GInt32 *panSrcScanline = nullptr;
    bool bTempFileAlreadyDeleted = false;

    if (eProxType == GDT_Byte || eProxType == GDT_UInt16 ||
        eProxType == GDT_UInt32)
    {
        GDALDriverH hDriver = GDALGetDriverByName("GTiff");
        if (hDriver == nullptr)
        {
            CPLError(CE_Failure, CPLE_AppDefined,
                     "GDALComputeProximity needs GTiff driver");
            eErr = CE_Failure;
            goto end;
        }
        CPLString osTmpFile = CPLGenerateTempFilenameSafe("proximity");
        hWorkProximityDS = GDALCreate(hDriver, osTmpFile, nXSize, nYSize, 1,
                                      GDT_Float32, nullptr);
        if (hWorkProximityDS == nullptr)
        {
            eErr = CE_Failure;
            goto end;
        }
        // On Unix, attempt at deleting the temporary file now, so that
        // if the process gets interrupted, it is automatically destroyed
        // by the operating system.
        bTempFileAlreadyDeleted = VSIUnlink(osTmpFile) == 0;
        hWorkProximityBand = GDALGetRasterBand(hWorkProximityDS, 1);
    }

    /* -------------------------------------------------------------------- */
    /*      Allocate buffer for two scanlines of distances as floats        */
    /*      (the current and last line).                                    */
    /* -------------------------------------------------------------------- */
    pafProximity =
        static_cast<float *>(VSI_MALLOC2_VERBOSE(sizeof(float), nXSize));
    panNearX = static_cast<int *>(VSI_MALLOC2_VERBOSE(sizeof(int), nXSize));
    panNearY = static_cast<int *>(VSI_MALLOC2_VERBOSE(sizeof(int), nXSize));
    panSrcScanline =
        static_cast<GInt32 *>(VSI_MALLOC2_VERBOSE(sizeof(GInt32), nXSize));

    if (pafProximity == nullptr || panNearX == nullptr || panNearY == nullptr ||
        panSrcScanline == nullptr)
    {
        eErr = CE_Failure;
        goto end;
    }

    /* -------------------------------------------------------------------- */
    /*      Loop from top to bottom of the image.                           */
    /* -------------------------------------------------------------------- */

    for (int i = 0; i < nXSize; i++)
    {
        panNearX[i] = -1;
        panNearY[i] = -1;
    }

    for (int iLine = 0; eErr == CE_None && iLine < nYSize; iLine++)
    {
        // Read for target values.
        eErr = GDALRasterIO(hSrcBand, GF_Read, 0, iLine, nXSize, 1,
                            panSrcScanline, nXSize, 1, GDT_Int32, 0, 0);
        if (eErr != CE_None)
            break;

        for (int i = 0; i < nXSize; i++)
            pafProximity[i] = -1.0;

        // Left to right.
        ProcessProximityLine(panSrcScanline, panNearX, panNearY, TRUE, iLine,
                             nXSize, dfMaxDist, pafProximity, pdfSrcNoData,
                             nTargetValues, panTargetValues);

        // Right to Left.
        ProcessProximityLine(panSrcScanline, panNearX, panNearY, FALSE, iLine,
                             nXSize, dfMaxDist, pafProximity, pdfSrcNoData,
                             nTargetValues, panTargetValues);

        // Write out results.
        eErr = GDALRasterIO(hWorkProximityBand, GF_Write, 0, iLine, nXSize, 1,
                            pafProximity, nXSize, 1, GDT_Float32, 0, 0);

        if (eErr != CE_None)
            break;

        if (!pfnProgress(0.5 * (iLine + 1) / static_cast<double>(nYSize), "",
                         pProgressArg))
        {
            CPLError(CE_Failure, CPLE_UserInterrupt, "User terminated");
            eErr = CE_Failure;
        }
    }

    /* -------------------------------------------------------------------- */
    /*      Loop from bottom to top of the image.                           */
    /* -------------------------------------------------------------------- */
    for (int i = 0; i < nXSize; i++)
    {
        panNearX[i] = -1;
        panNearY[i] = -1;
    }

    for (int iLine = nYSize - 1; eErr == CE_None && iLine >= 0; iLine--)
    {
        // Read first pass proximity.
        eErr = GDALRasterIO(hWorkProximityBand, GF_Read, 0, iLine, nXSize, 1,
                            pafProximity, nXSize, 1, GDT_Float32, 0, 0);

        if (eErr != CE_None)
            break;

        // Read pixel values.

        eErr = GDALRasterIO(hSrcBand, GF_Read, 0, iLine, nXSize, 1,
                            panSrcScanline, nXSize, 1, GDT_Int32, 0, 0);
        if (eErr != CE_None)
            break;

        // Right to left.
        ProcessProximityLine(panSrcScanline, panNearX, panNearY, FALSE, iLine,
                             nXSize, dfMaxDist, pafProximity, pdfSrcNoData,
                             nTargetValues, panTargetValues);

        // Left to right.
        ProcessProximityLine(panSrcScanline, panNearX, panNearY, TRUE, iLine,
                             nXSize, dfMaxDist, pafProximity, pdfSrcNoData,
                             nTargetValues, panTargetValues);

        // Final post processing of distances.
        for (int i = 0; i < nXSize; i++)
        {
            if (pafProximity[i] < 0.0)
                pafProximity[i] = fNoDataValue;
            else if (pafProximity[i] > 0.0)
            {
                if (bFixedBufVal)
                    pafProximity[i] = static_cast<float>(dfFixedBufVal);
                else
                    pafProximity[i] =
                        static_cast<float>(pafProximity[i] * dfDistMult);
            }
        }

        // Write out results.
        eErr = GDALRasterIO(hProximityBand, GF_Write, 0, iLine, nXSize, 1,
                            pafProximity, nXSize, 1, GDT_Float32, 0, 0);

        if (eErr != CE_None)
            break;

        if (!pfnProgress(0.5 + 0.5 * (nYSize - iLine) /
                                   static_cast<double>(nYSize),
                         "", pProgressArg))
        {
            CPLError(CE_Failure, CPLE_UserInterrupt, "User terminated");
            eErr = CE_Failure;
        }
    }

/* -------------------------------------------------------------------- */
/*      Cleanup                                                         */
/* -------------------------------------------------------------------- */
end:
    CPLFree(panNearX);
    CPLFree(panNearY);
    CPLFree(panSrcScanline);
    CPLFree(pafProximity);
    CPLFree(panTargetValues);

    if (hWorkProximityDS != nullptr)
    {
        CPLString osProxFile = GDALGetDescription(hWorkProximityDS);
        GDALClose(hWorkProximityDS);
        if (!bTempFileAlreadyDeleted)
        {
            GDALDeleteDataset(GDALGetDriverByName("GTiff"), osProxFile);
        }
    }

    return eErr;
}

/************************************************************************/
/*                         SquareDistance()                             */
/************************************************************************/

static double SquareDistance(double dfX1, double dfX2, double dfY1, double dfY2)
{
    const double dfDX = dfX1 - dfX2;
    const double dfDY = dfY1 - dfY2;
    return dfDX * dfDX + dfDY * dfDY;
}

/************************************************************************/
/*                        ProcessProximityLine()                        */
/************************************************************************/

static CPLErr ProcessProximityLine(GInt32 *panSrcScanline, int *panNearX,
                                   int *panNearY, int bForward, int iLine,
                                   int nXSize, double dfMaxDist,
                                   float *pafProximity,
                                   double *pdfSrcNoDataValue, int nTargetValues,
                                   int *panTargetValues)

{
    const int iStart = bForward ? 0 : nXSize - 1;
    const int iEnd = bForward ? nXSize : -1;
    const int iStep = bForward ? 1 : -1;

    for (int iPixel = iStart; iPixel != iEnd; iPixel += iStep)
    {
        bool bIsTarget = false;

        /* --------------------------------------------------------------------
         */
        /*      Is the current pixel a target pixel? */
        /* --------------------------------------------------------------------
         */
        if (nTargetValues == 0)
        {
            bIsTarget = panSrcScanline[iPixel] != 0;
        }
        else
        {
            for (int i = 0; i < nTargetValues; i++)
            {
                if (panSrcScanline[iPixel] == panTargetValues[i])
                    bIsTarget = TRUE;
            }
        }

        if (bIsTarget)
        {
            pafProximity[iPixel] = 0.0;
            panNearX[iPixel] = iPixel;
            panNearY[iPixel] = iLine;
            continue;
        }

        /* --------------------------------------------------------------------
         */
        /*      Are we near(er) to the closest target to the above (below) */
        /*      pixel? */
        /* --------------------------------------------------------------------
         */
        double dfNearDistSq = std::max(dfMaxDist, static_cast<double>(nXSize)) *
                              std::max(dfMaxDist, static_cast<double>(nXSize)) *
                              2.0;

        if (panNearX[iPixel] != -1)
        {
            const double dfDistSq = SquareDistance(panNearX[iPixel], iPixel,
                                                   panNearY[iPixel], iLine);

            if (dfDistSq < dfNearDistSq)
            {
                dfNearDistSq = dfDistSq;
            }
            else
            {
                panNearX[iPixel] = -1;
                panNearY[iPixel] = -1;
            }
        }

        /* --------------------------------------------------------------------
         */
        /*      Are we near(er) to the closest target to the left (right) */
        /*      pixel? */
        /* --------------------------------------------------------------------
         */
        const int iLast = iPixel - iStep;

        if (iPixel != iStart && panNearX[iLast] != -1)
        {
            const double dfDistSq =
                SquareDistance(panNearX[iLast], iPixel, panNearY[iLast], iLine);

            if (dfDistSq < dfNearDistSq)
            {
                dfNearDistSq = dfDistSq;
                panNearX[iPixel] = panNearX[iLast];
                panNearY[iPixel] = panNearY[iLast];
            }
        }

        /* --------------------------------------------------------------------
         */
        /*      Are we near(er) to the closest target to the topright */
        /*      (bottom left) pixel? */
        /* --------------------------------------------------------------------
         */
        const int iTR = iPixel + iStep;

        if (iTR != iEnd && panNearX[iTR] != -1)
        {
            const double dfDistSq =
                SquareDistance(panNearX[iTR], iPixel, panNearY[iTR], iLine);

            if (dfDistSq < dfNearDistSq)
            {
                dfNearDistSq = dfDistSq;
                panNearX[iPixel] = panNearX[iTR];
                panNearY[iPixel] = panNearY[iTR];
            }
        }

        /* --------------------------------------------------------------------
         */
        /*      Update our proximity value. */
        /* --------------------------------------------------------------------
         */
        if (panNearX[iPixel] != -1 &&
            (pdfSrcNoDataValue == nullptr ||
             panSrcScanline[iPixel] != *pdfSrcNoDataValue) &&
            dfNearDistSq <= dfMaxDist * dfMaxDist &&
            (pafProximity[iPixel] < 0 ||
             dfNearDistSq < static_cast<double>(pafProximity[iPixel]) *
                                pafProximity[iPixel]))
            pafProximity[iPixel] = static_cast<float>(sqrt(dfNearDistSq));
    }

    return CE_None;
}
